/* Return a basic set containing those elements in the space
* of aff where it is non-negative.
+ * If "rational" is set, then return a rational basic set.
*/
-__isl_give isl_basic_set *isl_aff_nonneg_basic_set(__isl_take isl_aff *aff)
+static __isl_give isl_basic_set *aff_nonneg_basic_set(
+ __isl_take isl_aff *aff, int rational)
{
isl_constraint *ineq;
isl_basic_set *bset;
ineq = isl_inequality_from_aff(aff);
bset = isl_basic_set_from_constraint(ineq);
+ if (rational)
+ bset = isl_basic_set_set_rational(bset);
bset = isl_basic_set_simplify(bset);
return bset;
}
+/* Return a basic set containing those elements in the space
+ * of aff where it is non-negative.
+ */
+__isl_give isl_basic_set *isl_aff_nonneg_basic_set(__isl_take isl_aff *aff)
+{
+ return aff_nonneg_basic_set(aff, 0);
+}
+
/* Return a basic set containing those elements in the domain space
* of aff where it is negative.
*/
for (i = 0; i < pwaff->n; ++i) {
isl_basic_set *bset;
isl_set *set_i;
+ int rational;
- bset = isl_aff_nonneg_basic_set(isl_aff_copy(pwaff->p[i].aff));
+ rational = isl_set_has_rational(pwaff->p[i].set);
+ bset = aff_nonneg_basic_set(isl_aff_copy(pwaff->p[i].aff),
+ rational);
set_i = isl_set_from_basic_set(bset);
set_i = isl_set_intersect(set_i, isl_set_copy(pwaff->p[i].set));
set = isl_set_union_disjoint(set, set_i);
return res;
}
+/* Compute the preimage of the affine expression "src" under "ma"
+ * and put the result in "dst". If "has_denom" is set (to one),
+ * then "src" and "dst" have an extra initial denominator.
+ * "n_div_ma" is the number of existentials in "ma"
+ * "n_div_bset" is the number of existentials in "src"
+ * The resulting "dst" (which is assumed to have been allocated by
+ * the caller) contains coefficients for both sets of existentials,
+ * first those in "ma" and then those in "src".
+ * f, c1, c2 and g are temporary objects that have been initialized
+ * by the caller.
+ *
+ * Let src represent the expression
+ *
+ * (a(p) + b x + c(divs))/d
+ *
+ * and let ma represent the expressions
+ *
+ * x_i = (r_i(p) + s_i(y) + t_i(divs'))/m_i
+ *
+ * We start out with the following expression for dst:
+ *
+ * (a(p) + 0 y + 0 divs' + f \sum_i b_i x_i + c(divs))/d
+ *
+ * with the multiplication factor f initially equal to 1.
+ * For each x_i that we substitute, we multiply the numerator
+ * (and denominator) of dst by c_1 = m_i and add the numerator
+ * of the x_i expression multiplied by c_2 = f b_i,
+ * after removing the common factors of c_1 and c_2.
+ * The multiplication factor f also needs to be multiplied by c_1
+ * for the next x_j, j > i.
+ */
+void isl_seq_preimage(isl_int *dst, isl_int *src,
+ __isl_keep isl_multi_aff *ma, int n_div_ma, int n_div_bset,
+ isl_int f, isl_int c1, isl_int c2, isl_int g, int has_denom)
+{
+ int i;
+ int n_param, n_in, n_out;
+ int o_div_bset;
+
+ n_param = isl_multi_aff_dim(ma, isl_dim_param);
+ n_in = isl_multi_aff_dim(ma, isl_dim_in);
+ n_out = isl_multi_aff_dim(ma, isl_dim_out);
+
+ o_div_bset = has_denom + 1 + n_param + n_in + n_div_ma;
+
+ isl_seq_cpy(dst, src, has_denom + 1 + n_param);
+ isl_seq_clr(dst + has_denom + 1 + n_param, n_in + n_div_ma);
+ isl_seq_cpy(dst + o_div_bset,
+ src + has_denom + 1 + n_param + n_out, n_div_bset);
+
+ isl_int_set_si(f, 1);
+
+ for (i = 0; i < n_out; ++i) {
+ if (isl_int_is_zero(src[has_denom + 1 + n_param + i]))
+ continue;
+ isl_int_set(c1, ma->p[i]->v->el[0]);
+ isl_int_mul(c2, f, src[has_denom + 1 + n_param + i]);
+ isl_int_gcd(g, c1, c2);
+ isl_int_divexact(c1, c1, g);
+ isl_int_divexact(c2, c2, g);
+
+ isl_int_mul(f, f, c1);
+ isl_seq_combine(dst + has_denom, c1, dst + has_denom,
+ c2, ma->p[i]->v->el + 1, ma->p[i]->v->size - 1);
+ isl_seq_scale(dst + o_div_bset,
+ dst + o_div_bset, c1, n_div_bset);
+ if (has_denom)
+ isl_int_mul(dst[0], dst[0], c1);
+ }
+}
+
/* Extend the local space of "dst" to include the divs
* in the local space of "src".
*/